Electronic band alignment and electron transport in Cr/BaTiO3/Pt ferroelectric tunnel junctions

Zenkevich, A.; Minnekaev, M.; Matveyev, Yu.; Lebedinskiǐ, Yu. Yu.; Bulakh, K.; Chouprik, Anastasia; Baturin, A. S.; Maksimova, Ksenia; Thieß, S.; Drube, W.

doi:10.1063/1.4792525

Cited by 73 publications

(59 citation statements)

References 24 publications

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“…They successively determined the interfacial BaTiO 3 /Pt and Cr/BaTiO 3 barrier heights, and used these parameters to fit I versus V DC measured on Cr/BaTiO 3 /Pt tunnel junctions in the ON and OFF states at room temperature. Hence, the OFF/ON ratio of 30 at room temperature in these FTJs can be interpreted by a modulation of the potential profile of the tunnel barrier in the direct tunnelling regime 41 .…”

Section: From Ter To Memristive Behaviourmentioning

confidence: 99%

“…There are, however, too many unknown physical parameters (dielectric constant, polarization, effective screening lengths, effective mass of tunnelling electrons and so on) to reasonably fit experimental data. To overcome this limitation, Zenkevich et al 41 performed hard X-ray photoemission experiments to gather more information on the electrode/ferroelectric interfacial electronic properties. They successively determined the interfacial BaTiO 3 /Pt and Cr/BaTiO 3 barrier heights, and used these parameters to fit I versus V DC measured on Cr/BaTiO 3 /Pt tunnel junctions in the ON and OFF states at room temperature.…”

Section: From Ter To Memristive Behaviourmentioning

confidence: 99%

“…However, some influence of electrochemical phenomena correlated with ferroelectric polarization switching cannot be completely excluded 40 . Alongside with ab initio calculations 42,55 , investigations of the actual metal/ferroelectric interfaces with spectroscopic techniques, such as X-ray photoemission spectroscopy 41 and advanced transmission electron microscopy-based techniques 88,89 , will bring further insights on the understanding of TER.…”

Section: Electrical Control Of Spin-polarizationmentioning

confidence: 99%

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Ferroelectric tunnel junctions for information storage and processing

2014

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Computer memory that is non-volatile and therefore able to retain its information even when switched off enables computers that do not need to be booted up. One of the technologies for such applications is ferroelectric random access memories, where information is stored as ferroelectric polarization. To miniaturize such devices to the size of a few nanometres, ferroelectric tunnel junctions have seen considerable interest. There, the electric polarization determines the electrical resistance of these thin films, switching the current on and off. With control over other parameters such as magnetism also being possible, ferroelectric tunnel junctions represent a promising and flexible device design. F erroelectric random access memories (FeRAMs), in which information is encoded through the ferroelectric polarization, are commercially available products with fast write speed, large read/write cycle endurance and low-power consumption 1 . In these ferroelectric capacitors, a ferroelectric thin film (typically 100 nm thick) is sandwiched between two electrodes and the remnant polarization is switched by applying an electric field between the electrodes. The widespread development of these memories is however limited owing to the capacitive readout of the information (the polarization) that prevents the scalability of FeRAMs up to gigabit densities and necessitates the rewriting of information after readout (destructive readout) 2 . In ferroelectric diodes, the current across a thick ferroelectric can be modulated by the polarization at the ferroelectric/electrode interface, giving rise to a non-destructive, resistive readout of the information 3,4 . But in these devices, the large thickness of the ferroelectric layer results in very low readout currents, limiting their miniaturization. As the ferroelectric layer thickness is decreased to a few nanometres, electronic conduction is greatly enhanced as quantum-mechanical tunnelling through the ferroelectric becomes possible 5,6 . These devices in which two electrodes sandwich a ferroelectric tunnel barrier are called ferroelectric tunnel junctions (FTJs). The tunnel transmission may be strongly modulated by the ferroelectric polarization producing giant tunnel electroresistance (TER) with OFF/ON resistance ratios reaching 10 4 (refs 7,8). Moreover, the readout current densities are much larger than in ferroelectric diodes, thereby opening the path to possible applications as high-density ferroelectric memories with non-destructive readout.Here we review the fast progress of the nascent field of FTJs and give perspectives for new physical effects and future applications. We first summarize possible electron transport mechanisms that occur when voltage is applied across ultrathin films of ferroelectrics. We then focus on experimental reports that evidence a direct correlation between ferroelectric switching and resistive switching, from local probes experiments on ferroelectric surfaces to solid-state

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Section: From Ter To Memristive Behaviourmentioning

confidence: 99%

Section: From Ter To Memristive Behaviourmentioning

confidence: 99%

Section: Electrical Control Of Spin-polarizationmentioning

confidence: 99%

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Ferroelectric tunnel junctions for information storage and processing

2014

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“…Nevertheless, high-quality epitaxial films grown on suitable substrates were found to possess necessary ferroelectric properties even at nanoscale thicknesses [14][15][16][17][18] , which may be attributed to the enhancement of the out-of-plane polarization by substrate-induced lattice strains 19 and the elastic stabilization of a single-domain state 20 . Based on these advancements, various FTJs have recently been successfully fabricated and the TER effect was revealed experimentally and confirmed theoretically [21][22][23][24][25][26][27][28][29][30][31] . Moreover, the functioning of solid-state memories based on FTJs has been demonstrated 3,32 and the memristive behaviour with resistance variations exceeding two orders of magnitude was observed for FTJs with the BaTiO 3 (BTO) barrier 32,33 .…”

mentioning

confidence: 99%

“…The choice of electrode materials, due to different screening and chemical properties at the interface, seems to have pronounced influence on the TER effect [21][22][23][24][25][26][27][28][29][30][31][32][33] . Therefore, it is essential to examine the impact of different electrode materials on the TER characteristics of FTJs.…”

mentioning

confidence: 99%

Giant electrode effect on tunnelling electroresistance in ferroelectric tunnel junctions

et al. 2014

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Among recently discovered ferroelectricity-related phenomena, the tunnelling electroresistance (TER) effect in ferroelectric tunnel junctions (FTJs) has been attracting rapidly increasing attention owing to the emerging possibilities of non-volatile memory, logic and neuromorphic computing applications of these quantum nanostructures. Despite recent advances in experimental and theoretical studies of FTJs, many questions concerning their electrical behaviour still remain open. In particular, the role of ferroelectric/electrode interfaces and the separation of the ferroelectric-driven TER effect from electrochemical ('redox'-based) resistance-switching effects have to be clarified. Here we report the results of a comprehensive study of epitaxial junctions comprising BaTiO 3 barrier, La 0.7 Sr 0.3 MnO 3 bottom electrode and Au or Cu top electrodes. Our results demonstrate a giant electrode effect on the TER of these asymmetric FTJs. The revealed phenomena are attributed to the microscopic interfacial effect of ferroelectric origin, which is supported by the observation of redox-based resistance switching at much higher voltages.

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Ferroelectric/Multiferroic Tunnel Junctions for Multifunctional Applications

Ortega

Barrionuevo

Kumar

et al. 2015

Wiley Encyclopedia of Electrical and Electronics Engineering

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Ferroelectric and multiferroic tunnel junctions (FTJ/MFTJs) are a novel class of next generation nonvolatile memories devices that display simultaneous magnetic spin, electric dipole ordering, and tunneling with cross coupling and have drawn increasing interest due to their multifunctionality for a variety of device applications. With the rapid development of thin‐film growth techniques and characterization tools in the last decade, it is possible to do extensive research in the area of polar barrier tunnel junctions (TJ). This chapter summarizes how the ferroelectric (FE) (polar) nature of the barrier changes the tunneling probability, and briefly, we expose several aspects to be considered in the synthesis of FTJ and MFTJ, such as critical thickness for ferroelectricity, effect of the depolarization field, and the role of interface on ferroelectricity at the nanoscale level. In addition, we include recent research results in FTJ/MFTJ. We focus in particular on PZT (lead zirconate titanate) and BTO (barium titanate) in case of ferroelectric tunnel junction (FTJ), and BFO (bismuth ferrite) and BMO (bismuth manganite) single‐phase multiferroics (MFs) used as barriers in multiferroic tunnel junctions (MFTJ). The variety of interesting physical phenomena of these TJ and their multifunctional properties for various technological applications make the research in this field challenging and promising.

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Electronic band alignment and electron transport in Cr/BaTiO3/Pt ferroelectric tunnel junctions

Cited by 73 publications

References 24 publications

Ferroelectric tunnel junctions for information storage and processing

Ferroelectric tunnel junctions for information storage and processing

Giant electrode effect on tunnelling electroresistance in ferroelectric tunnel junctions

Ferroelectric/Multiferroic Tunnel Junctions for Multifunctional Applications

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